Massive Acceleration of S2 Reaction Using the Oriented External Electric Field

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2024 Aug 26

PMID 39183916

Authors

Chun Tang

Meiling Su

Taige Lu

Jueting Zheng

Juejun Wang

Yu Zhou

Yu-Ling Zou

Wenqing Liu

Ruiyun Huang

Wei Xu

Lijue Chen

Yanxi Zhang

Jie Bai

Yang Yang

Jia Shi

Junyang Liu

Wenjing Hong

Affiliations

Soon will be listed here.

Abstract

Nucleophilic substitution is one of the most fundamental chemical reactions, and the pursuit of high reaction rates of the reaction is one of the ultimate goals in catalytic and organic chemistry. The reaction barrier of the nucleophilic substitution originates from the highly polar nature of the transition state that can be stabilized under the electric field created by the solvent environment. However, the intensity of the induced solvent-electric field is relatively small due to the random orientation of solvent molecules, which hinders the catalytic effects and restricts the reaction rates. This work shows that oriented external electric fields applied within a confined nanogap between two nanoscopic tips could accelerate the Menshutkin reaction by more than four orders of magnitude (over 39 000 times). The theoretical calculations reveal that the electric field inside the nanogap reduces the energy barrier to increase the reaction rate. Our work suggests the great potential of electrostatic catalysis for green synthesis in the future.

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